Cerebral blood flow response to cardiorespiratory oscillations in healthy humans.

Dynamic cerebral autoregulation (CA) characterizes the cerebral blood flow (CBF) response to abrupt changes in arterial blood pressure (ABP). CA operates at frequencies below 0.15 Hz. ABP regulation and probably CA are modified by autonomic nervous activity. We investigated the CBF response and CA dynamics to mild increase in sympathetic activity. Twelve healthy volunteers underwent oscillatory lower body negative pressure (oLBNP), which induced respiratory-related ABP oscillations at an average of 0.22 Hz. We recorded blood velocity in the internal carotid artery (ICA) by Doppler ultrasound and ABP. We quantified variability and peak wavelet power of ABP and ICA blood velocity by wavelet analysis at low frequency (LF, 0.05-0.15 Hz) and Mayer waves (0.08-0.12 Hz), respectively. CA was quantified by calculation of the wavelet synchronization gamma index for the pair ABP-ICA blood velocity in the LF and Mayer wave band. oLBNP increased ABP peak wavelet power at the Mayer wave frequency. At the Mayer wave, ABP peak wavelet power increased by >70 % from rest to oLBNP (p < 0.05), while ICA blood flow velocity peak wavelet power was unchanged, and gamma index increased (from 0.49 to 0.69, p < 0.05). At LF, variability in both ABP and ICA blood velocity and gamma index were unchanged from rest to oLBNP. Despite an increased gamma index at Mayer wave, ICA blood flow variability was unchanged during increased ABP variability. The increased synchronization during oLBNP did not cause less stable CBF or less active CA. Sympathetic activation seems to improve the mechanisms of CA.

Oscillatory pattern of acral skin blood flow within thermoneutral zone in healthy humans.

The acral skin contains arteriovenous anastomoses, which probably is the main part of skin microcirculation for blood flow adjustments and thermoregulation in the thermoneutral zone. The objective was to investigate if an increase in sympathetic activation during cooling influences the oscillatory pattern of acral skin blood flow. We had measurements of bilateral acral skin blood flow (n = 12) during lowering of ambient temperature from 32 °C to 18 °C. We quantified the oscillatory pattern as the time averaged wavelet spectral powers, coherence and phase angles in three frequency intervals (0.01-0.02 Hz, 0.02-0.05 Hz and 0.05-0.08 Hz). The differences were tested by Wilcoxon signed rank sum method between adjacent intervals. The absolute fluctuations in laser Doppler flux at 0.01-0.02 Hz, 0.02-0.05 Hz and 0.05-0.08 Hz were similar at 32 °C and 25 °C, and decreased at 18 °C (p < 0.001). The relative fluctuations (amplitude of the fluctuations relative to median flux value) in laser Doppler flux at 0.01-0.02 Hz, 0.02-0.05 Hz and 0.05-0.08 Hz were higher at 25 °C and 18 °C as compared to 32 °C (p < 0.002). The coherence between the oscillations of signals from right and left finger tips was highest (median coherence > 0.89) at 25 °C, and lower at 32 °C and at 18 °C.The median phase angles between the flux signals from right and left finger tips were close to 0 radians. We found that the relative fluctuations in acral skin blood flow increased during vasoconstriction due to cooling. Wavelet analysis of acral skin blood flow oscillations could serve as a future clinical tool.